Bed Evolution under One-Episode Flushing in a Truck Sewer in Paris, France
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Bed Evolution under One-Episode Flushing in a Truck Sewer in Paris, France

Authors: Gashin Shahsavari, Gilles Arnaud-Fassetta, Roberto Bertilotti, Alberto Campisano, Fabien Riou

Abstract:

Sewer deposits have been identified as a major cause of dysfunctions in combined sewer systems regarding sewer management, which induces different negative consequents resulting in poor hydraulic conveyance, environmental damages as well as worker’s health. In order to overcome the problematics of sedimentation, flushing has been considered as the most operative and cost-effective way to minimize the sediments impacts and prevent such challenges. Flushing, by prompting turbulent wave effects, can modify the bed form depending on the hydraulic properties and geometrical characteristics of the conduit. So far, the dynamics of the bed-load during high-flow events in combined sewer systems as a complex environment is not well understood, mostly due to lack of measuring devices capable to work in the “hostile” in combined sewer system correctly. In this regards, a one-episode flushing issue from an opening gate valve with weir function was carried out in a trunk sewer in Paris to understand its cleansing efficiency on the sediments (thickness: 0-30 cm). During more than 1h of flushing within 5 m distance in downstream of this flushing device, a maximum flowrate and a maximum level of water have been recorded at 5 m in downstream of the gate as 4.1 m3/s and 2.1 m respectively. This paper is aimed to evaluate the efficiency of this type of gate for around 1.1 km (from the point -50 m to +1050 m in downstream from the gate) by (i) determining bed grain-size distribution and sediments evolution through the sewer channel, as well as their organic matter content, and (ii) identifying sections that exhibit more changes in their texture after the flush. For the first one, two series of sampling were taken from the sewer length and then analyzed in laboratory, one before flushing and second after, at same points among the sewer channel. Hence, a non-intrusive sampling instrument has undertaken to extract the sediments smaller than the fine gravels. The comparison between sediments texture after the flush operation and the initial state, revealed the most modified zones by the flush effect, regarding the sewer invert slope and hydraulic parameters in the zone up to 400 m from the gate. At this distance, despite the increase of sediment grain-size rages, D50 (median grainsize) varies between 0.6 mm and 1.1 mm compared to 0.8 mm and 10 mm before and after flushing, respectively. Overall, regarding the sewer channel invert slope, results indicate that grains smaller than sands (< 2 mm) are more transported to downstream along about 400 m from the gate: in average 69% before against 38% after the flush with more dispersion of grain-sizes distributions. Furthermore, high effect of the channel bed irregularities on the bed material evolution has been observed after the flush.

Keywords: Bed-material load evolution, combined sewer systems, flushing efficiency, sediment transport.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1108458

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References:


[1] G. Chebbo, D. Laplace, A. Bachoc, Y. Sanchez, and B. Le Guennec, ‘Technical solutions envisaged in managing solids in combined sewer networks’, Water Sci. Technol., vol. 33, no. 9, pp. 237–244, 1996.
[2] R. M. Ashley, J. L. Bertrand-Krajewski, T. Hvitved-Jacobsen, and M. A. Verbanck, Solids in sewers - Characteristics, effects and control of sewer solids and associated pollutants. 2005.
[3] W. C. Pisano, G. L. Aronson, C. S. Queiroz, F. C. Blanc, and J. C. O. Shaughnessy, ‘Dry-weather deposition and flushing for combined sewer’, 1979.
[4] J. L. Bertrand-Krajewski, A. Campisano, E. Creaco, and C. Modica, ‘Experimental analysis of the hydrass flushing gate and field validation of flush propagation modelling.’, Water Sci. Technol., vol. 51, no. 2, pp. 129–37, Jan. 2005.
[5] E. Ristenpart, ‘Solids transport by flushing of combined sewers’, Water Sci. Technol., vol. 37, no. 1, pp. 171–178, 1998.
[6] E. Ristenpart, ‘Sediment properties and their changes in a sewer’, Water Sci. Technol., vol. 31, no. 7, pp. 77–83, 1995.
[7] Y. L. Lau and I. G. Droppo, ‘Influence of antecedent conditions on critical shear stress of bed sediments’, Water Res., vol. 34, no. 2, pp. 663–667, 2000.
[8] R. H. S. M. Shirazi, R. Bouteligier, P. Willems, and J. Berlamont, ‘Preliminary results of investigating proper location of flushing tanks in combined sewer networks for optimum effect’, in 11th international Conference on Urban Drainage, 2008, pp. 1–9.
[9] A. Campisano and C. Modica, ‘Flow velocities and shear stresses during flushing operations in sewer collectors.’, Water Sci. Technol., vol. 47, no. 4, pp. 123–8, Jan. 2003.
[10] A. Campisano, E. Creaco, and C. Modica, ‘Dimensionless approach for the design of flushing gates in sewer channels’, J. Hydraul. Eng., vol. 133, no. 8, pp. 964–972, 2007.
[11] A. Campisano, E. Creaco, and C. Modica, ‘Laboratory investigation on the effects of flushes on cohesive sediment beds’, Urban Water J., vol. 5, no. 1, pp. 3–14, Mar. 2008.
[12] C. H. J. Bong, T. L. Lau, and A. Ab Ghani, ‘Hydraulics characteristics of tipping sediment flushing gate.’, Water Sci. Technol., vol. 68, no. 11, pp. 2397–406, Jan. 2013.
[13] A. Campisano, E. Creaco, and C. Modica, ‘Experimental analysis of the Hydrass flushing gate and laboratory validation of flush propagation modelling’, Water Sci. Technol., vol. 54, no. 6–7, p. 101, Oct. 2006.
[14] S. Todeschini, C. Ciaponi, and S. Papiri, ‘Experimental and numerical analysis of erosion and sediment transport of flushing waves’, pp. 1–10, 2008.
[15] J. Dettmar and P. Staufer, ‘Behavior of the activated storage-volume of flushing waves on cleaning performance’, in Proc. 10th Int. Conf. on Urban Drainage, 2005, no. August, pp. 1–8.
[16] P. Balayn, ‘Modélisation du transfert de sédiments lors d’un lâcher d'eau en réseau d'assainissement – approche numérique’, 1996.
[17] T. Sakakibara, ‘Sediments flushing experiment in a trunk sewer’, Water Sci. Technol., vol. 33, no. 9, pp. 229–235, 1996.
[18] J. Dettmar and P. Staufer, ‘Modelling of Flushing Waves for Optimising Cleaning Operations’, in Urban Drainage Modelling, 2004, pp. 241– 248.
[19] K. El Kadi A. and A. Paquier, ‘Numerical modeling of flushing waves in sewer channels’, Novatech, vol. session 6., pp. 1285–1292, 2007.
[20] Q. Guo, C. Y. Fan, R. Raghaven, and R. Field, ‘Gate and Vacuum Flushing of Sewer Sediment: Laboratory Testing’, J. Hydraul. Eng., vol. 130, no. 5, pp. 463–466, 2004.
[21] K. J. J. Williams, S. J. Tait, and R. M. Ashley, ‘In-sewer sedimentation associated with active flow control’, Water Sci. Technol., vol. 60, no. 1, pp. 55–63, Jan. 2009.
[22] P. Staufer and J. Pinnekamp, ‘In situ measurements of shear stresses of a flushing wave in a circular sewer using ultrasound’, Water Sci. Technol., vol. 57, no. 9, pp. 1363–1368, 2008.
[23] A. Lorenzen, E. Ristenpart, and W. Pfuhl, ‘Flush cleaning of sewers’, Water Sci. Technol., vol. 33, no. 9, pp. 221–228, 1996.
[24] M. H. García, Sedimentation engineering. 2008.
[25] ORSTOM, ‘Méthodes d’analyses utilisées au laboratoire de physique des sols.’
[26] P. Staufer, J. Dettmar, and J. Pinnekamp, ‘Upstream processes within a flushing wave’, in Urban Drainage, 2008, no. 2005, pp. 1–10.
[27] H. Chamley, Sedimentology. Springer, 1990.
[28] R. W. Crabtree, ‘Sediments in Sewers’, Water Environ. J., vol. 3, no. 6, pp. 569–578, 1989.
[29] M. Ahyerre, C. Oms, and G. Chebbo, ‘The erosion of organic solids in combined sewers’, Water Sci. Technol., vol. 43, pp. 95–102, 2001.
[30] D. Laplace, C. Oms, M. Ahyerre, G. Chebbo, J. Lemasson, and L. Felouzis, ‘Removal of the organic surface layer in combined sewer sediment using a flushing gate’, Water Sci. Technol., vol. 47, no. 4, pp. 19–26, 2003.
[31] C. Oms, M. C. Gromaire, and G. Chebbo, ‘In situ observation of the water-sediment interface in combined sewers, using endoscopy’, Water Sci. Technol., vol. 47, no. 4, pp. 11–18, 2003.
[32] W. C. Pisano, J. Barsanti, and J. Joyce, ‘Sewer and Tank Sediment Flushing, Case Studies’, no. December, p. 113, 1998.
[33] J. L. Bertrand-Krajewski, J. P. Bardin, C. Gibello, and D. Laplace, ‘Hydraulics of a sewer flushing gate’, Water Sci. Technol., vol. 47, no. 4, pp. 129–136, 2003.
[34] T. Walski, J. Falco, M. McAloon, and B. Whitman, ‘Transport of large solids in unsteady flow in sewers’, Urban Water J., vol. 8, no. 3, pp. 179–187, Jun. 2011.
[35] P. Staufer, J. Dettmar, and J. Pinnekamp, ‘Improvement of water quality by sewer network flushing’, Novatech, pp. 1317–1324, 2007.
[36] Www.meteociel.fr, ‘Meteociel.’.